Specific MHC class I supertype associated with

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Received: 2 July 2018    Revised: 19 July 2018    Accepted: 23 July 2018 DOI: 10.1002/ece3.4479

ORIGINAL RESEARCH

Specific MHC class I supertype associated with parasite infection and color morph in a wild lizard population Jessica D. Hacking1

 | Devi Stuart-Fox2 | Stephanie S. Godfrey3 | Michael G. Gardner1,4

1

College of Science and Engineering, Flinders University, Bedford Park, South Australia, Australia

2

School of BioSciences, University of Melbourne, Parkville, Victoria, Australia

3 Department of Zoology, University of Otago, Dunedin, New Zealand 4

Evolutionary Biology Unit, South Australian Museum, Adelaide, South Australia, Australia Correspondence Jessica D. Hacking, College of Science and Engineering, Flinders University, Bedford Park, SA, Australia. Email: [email protected] Funding information Wildlife Preservation Society of Australia; Royal Society of South Australia; Flinders University Interfaculty Collaboration

Abstract The major histocompatibility complex (MHC) is a large gene family that plays a central role in the immune system of all jawed vertebrates. Nonavian reptiles are underrepresented within the MHC literature and little is understood regarding the mechanisms maintaining MHC diversity in this vertebrate group. Here, we examined the relative roles of parasite-­mediated selection and sexual selection in maintaining MHC class I diversity of a color polymorphic lizard. We discovered evidence for parasite-­mediated selection acting via rare-­allele advantage or fluctuating selection as ectoparasite load was significantly lower in the presence of a specific MHC supertype (functional clustering of alleles): supertype four. Based on comparisons between ectoparasite prevalence and load, and assessment of the impact of ectoparasite load on host fitness, we suggest that supertype four confers quantitative resistance to ticks or an intracellular tickborne parasite. We found no evidence for MHC-­associated mating in terms of pair genetic distance, number of alleles, or specific supertypes. An association was uncovered between supertype four and male throat color morph. However, it is unlikely that male throat coloration acts as a signal of MHC genotype to conspecifics because we found no evidence to suggest that male throat coloration predicts male mating status. Overall, our results suggest that parasite-­mediated selection plays a role in maintaining MHC diversity in this population via rare-­allele advantage and/or fluctuating selection. Further work is required to determine whether sexual selection also plays a role in maintaining MHC diversity in agamid lizards. KEYWORDS

Agamidae, Ctenophorus decresii, major histocompatibility complex, MHC-associated mating, parasite-mediated selection

1 |  I NTRO D U C TI O N

consequences of disease (Acevedo-­ Whitehouse & Cunningham, 2006). The major histocompatibility complex (MHC) is an extremely

Pathogen–host relationships can strongly influence ecological and

diverse gene family that plays a central role within the immune sys-

evolutionary processes within wild populations (Harvell, 2004).

tem of all jawed vertebrates (Kulski, Shiina, Anzai, Kohara, & Inoko,

Understanding the mechanisms shaping host immunity is required

2002). Both parasite-­mediated selection and sexual selection have

for wildlife disease management and to evaluate the evolutionary

been found to maintain this diversity (Piertney & Oliver, 2006).

This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. © 2018 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd. Ecology and Evolution. 2018;1–15.

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However, these alternative sources of selection are rarely examined

(high or intermediate), compatibility (high or intermediate diversity in

together in the same species, limiting the ability to explore their

offspring), and/or based on specific alleles or supertypes (Ejsmond,

relative roles (although see Dunn, Bollmer, Freeeman-­ Gallant, &

Radwan, & Wilson, 2014). Spatial or temporal differences in mate

Whittingham, 2012; Eizaguirre et al., 2010; Sepil, Lachish, Hinks, &

choice for MHC characteristics may also occur (fluctuating selection,

Sheldon, 2013; Sepil et al., 2015).

Cutrera, Zenuto, & Lacey, 2014). In some systems, sexual selection

Evidence for parasite-­mediated selection acting on MHC genes

may play a large role in maintaining MHC diversity. For instance,

via rare-­ allele advantage (Borghans, Beltman, & De Boer, 2004;

Winternitz et al. (2013) found that sexual selection explains more

Schwensow et al., 2017), fluctuating selection (Jones, Cheviron, &

functional variation than parasite-­mediated selection in mammals.

Carling, 2015; Osborne, Pilger, Lusk, & Turner, 2017), heterozygote

Two nonmutually exclusive hypotheses are used to explain

advantage (Doherty & Zinkernagel, 1975; Takahata & Nei, 1990),

MHC-­associated mating: the good genes hypothesis and the com-

and optimal intermediate diversity advantage (Wegner, Kalbe, Kurtz,

plementary genes hypothesis. The good genes hypothesis involves

Reusch, & Milinski, 2003) has been uncovered across a range of

mating that is influenced by MHC diversity, or specific alleles or su-

taxa. However, most evidence points toward rare-­allele advantage

pertypes, irrespective of the genotype of the choosy sex (absolute

and fluctuating selection as the dominant mechanisms by which

criteria, Brown, 1997; Hamilton & Zuk, 1982). The complementary

pathogen-­mediated selection maintains MHC diversity, with little

genes hypothesis predicts that mating is based on MHC genotype

evidence that heterozygote advantage alone can account for the ex-

compatibility between mates (self-­referential criteria, Zeh & Zeh,

treme diversity found at MHC loci (De Boer, Borghans, van Boven,

1996). Hence, the genotype of the choosy sex is considered during

Kesmir, & Weissing, 2004).

mate choice. These hypotheses are used to test for evidence of het-

Individual MHC alleles or supertypes (functional clustering of

erozygote or intermediate diversity advantage, or associations with

alleles) may provide resistance against (Savage & Zamudio, 2011;

certain alleles or supertypes, indicating rare-­ allele advantage or

Sepil et al., 2013), allow tolerance of (Regoes et al., 2014), or cause

fluctuating selection (Spurgin & Richardson, 2010). Both olfactory

susceptibility to infection (Carrington et al., 1999). Interpreting the

(Boehm & Zufall, 2006; Milinski et al., 2005; Setchell et al., 2011;

nature of such relationships requires information on both parasite

Strandh et al., 2012) and visual (Dunn et al., 2012; Hinz, Gebhardt,

prevalence and load, and the impact of infection on host fitness,

Hartmann, Sigman, & Gerlach, 2012; Milinski, 2014; Olsson et al.,

data which are often difficult to obtain for populations in the wild

2005) traits have been proposed to signal individual MHC geno-

(Råberg, 2014; Råberg, Sim, & Read, 2007). Resistance may come in

types to conspecifics in mammals, birds, and fish. For instance, Dunn

the form of complete (qualitative) or partial (quantitative) protection

et al. (2012) found that the male black facial masks of common yel-

against parasites (Westerdahl, Asghar, Hasselquist, & Bensch, 2011).

lowthroat birds likely act as a signal of MHC diversity to mates, and

Under qualitative resistance, the host prevents the establishment of

MHC-­dependent peptides in mouse urine may signal MHC genotype

infection and completely clears infection. Quantitative resistance,

to conspecifics (Sturm et al., 2013). However, the phenotypic traits

on the other hand, allows the host to suppress parasite load but not

used by reptiles and amphibians to signal MHC genotype to conspe-

completely clear infection. Tolerance may co-­occur with quantitative

cifics are largely unknown.

resistance and refers to the ability of the host to withstand high par-

Here, we examined the relative roles of sexual selection and

asite load without impacting fitness (Regoes et al., 2014). Tolerance

parasite-­mediated selection in maintaining MHC diversity within

is measured as the gradient of the relationship between Darwinian

a wild reptile population. The Australian tawny dragon lizard

fitness (or a proxy of fitness) and infection intensity (Råberg, 2014).

(Ctenophorus decresii), for which MHC class I has been characterized

Finally, parasite counteradaptations to host defenses may cause

(Hacking, Bertozzi, Moussalli, Bradford, & Gardner, 2018), is host to

certain MHC alleles or supertypes to increase host susceptibility to

both ectoparasites and intracellular parasites (Hacking et al., unpub-

infection (Kubinak, Ruff, Hyzer, Slev, & Potts, 2012). Understanding

lished data). Male C. decresii exhibit secondary sexual coloration on

the nature of host–parasite relationships is important as differ-

their throat and chest that is emphasized in displays to conspecifics

ent types of relationships have different consequences for epide-

(Gibbons, 1979; Osborne, 2005a,b; Osborne, Umbers, Backwell, &

miology and the evolutionary dynamics of both host and parasite

Keogh, 2012; Stuart-­Fox & Johnston, 2005). Furthermore, in some

(Westerdahl et al., 2011).

populations four discrete male throat color morphs coexist. Hence,

MHC-­ associated mate choice has been discovered in most

C. decresii represents an excellent model to investigate patterns of

vertebrate classes, including bony fish (Evans, Dionne, Miller,

MHC variation, parasites, and visual signals. First, we investigated

& Bernatchez, 2012; Reusch, Häberli, Aeschlimann, & Milinski,

the role that parasite-­mediated selection plays in maintaining MHC

2001), amphibians (Bos, Williams, Gopurenko, Bulut, & DeWoody,

diversity by testing the hypothesis that specific MHC supertypes

2009), reptiles (Miller, Moore, Nelson, & Daugherty, 2009; Olsson

are associated with parasite prevalence and/or load. We then de-

et al., 2003; Pearson, Godfrey, Schwensow, Bull, & Gardner, 2017),

termined whether MHC–parasite relationships were associated

birds (Juola & Dearborn, 2012; Strandh et al., 2012), and mam-

with resistance, tolerance, or susceptibility. Second, we asked

mals (Cutrera, Fanjul, & Zenuto, 2012; Schad, Dechmann, Voigt, &

whether sexual selection, via MHC-­associated mating, plays a role

Sommer, 2012). Mate choice may be influenced by MHC diversity

in maintaining MHC diversity. In a specific manner, we tested the

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HACKING et al.

hypothesis that MHC diversity and/or mate MHC compatibility pre-

between the MHC and arachnid ectoparasites have been uncovered

dicts male mating status while accounting for the spatial position of

in both mammals (Kamath, Turner, Kusters, & Getz, 2014; Oliver,

mates, pair relatedness, and mate overall genetic diversity. Finally,

Telfer, & Piertney, 2009; Schad et al., 2012) and reptiles (Radwan,

we investigated visual phenotypic traits that may signal MHC geno-

Kuduk, Levy, LeBas, & Babik, 2014). Immune defense against he-

type to conspecifics.

matophageous ectoparasites involves class II MHC molecules and likely also MHC class I molecules via cross-­presentation (Andrade, Teixeira, Barral, & Barral-­Netto, 2005; Rock, Reits, & Neefjes, 2016;

2 | M ATE R I A L S A N D M E TH O DS

Wikel, 1996). Furthermore, arachnid ectoparasites (ticks and mites) have been found to transmit vectorborne intracellular parasites such as protists, viruses, and bacteria to reptile hosts (Allison &

2.1 | Male mating status

Desser, 1981; Bonorris & Ball, 1955; Camin, 1948; Chaisiri, McGarry,

The tawny dragon is a small (